Charger circuit and capacitive power conversion circuit and reverse blocking switch circuit thereof

1. A charger circuit, configured to operably convert an input power to a DC power and convert the DC power to a charging power for charging a battery, wherein the DC power includes a DC voltage and a DC current and the charging power includes a charging voltage and a charging current; the charger circuit comprising: a power delivery unit, configured to operably convert the input power to the DC power; and at least one capacitive power conversion circuit, including: a conversion switch circuit, configured to operably convert the DC power to a converted output power which includes a converted output voltage and a converted output current, wherein the charging power is related to the converted output power; wherein the conversion switch circuit includes plural conversion switches, configured to be coupled to at least one conversion capacitor, wherein at least one of the conversion switches includes a body diode; a control circuit, configured to operably generate a conversion switch control signal to control the plural conversion switches; and at least one reverse blocking switch circuit, coupled with the battery and the conversion switch circuit in series, and configured to block a parasitic body current flowing through the body diode of the conversion switch, wherein the reverse blocking switch circuit includes at least one reverse blocking switch which has a body diode, and the body diode of the reverse blocking switch is reversely coupled to said body diode of the conversion switch; wherein in a charging mode, the power delivery unit regulates the DC current to a predetermined DC current level, and/or regulates the DC voltage to a predetermined DC voltage level, and during plural charging conversion time periods in a cycle period, the conversion switch control signal operates the plural conversion switches so as to electrically connect the conversion capacitor between a pair of nodes selected from one or more charging voltage division nodes, the DC voltage, and a ground node periodically, such that the charging current is scaled-up of the predetermined DC current level substantially by a predetermined factor, the factor being larger than 1 whereby the charging current is larger than the DC output current, and/or the charging voltage is substantially a predetermined voltage ratio of the predetermined DC voltage level; wherein the converted output power is generated through one of the one or more charging voltage division nodes.

2. The charger circuit of claim 1 , wherein the reverse blocking switch is connected in series between the power delivery unit and the capacitive power conversion circuit, or between the battery and the capacitive power conversion circuit.

3. The charger circuit of claim 1 , wherein the charger circuit includes plural capacitive power conversion circuits and the reverse blocking switch circuit includes plural reverse blocking switches, wherein the plural capacitive power conversion circuits are coupled in parallel and/or the plural reverse blocking switches are coupled in parallel.

4. The charger circuit of claim 1 , wherein the reverse blocking switch circuit further includes a regulation protection switch and a first regulation comparator and/or a second regulation comparator, wherein the first regulation comparator is configured to operably compare a charging current related signal and a regulation current threshold to generate a regulation current comparison result, and control the regulation protection switch according to the regulation current comparison result, such that the charging current is regulated to be not larger than a predetermined regulation current level; and the second regulation comparator is configured to operably compare a charging voltage related signal and a regulation voltage threshold to generate a regulation voltage comparison result, and control the regulation protection switch according to the regulation voltage comparison result, such that the charging voltage is regulated to be not larger than a predetermined regulation voltage level.

5. The charger circuit of claim 1 , wherein the capacitive power conversion circuit and the reverse blocking switch circuit are integrated into an integrated circuit or packaged into an integrated circuit package.

6. The charger circuit of claim 5 , further including at least an over voltage protection switch, wherein a voltage rating of an input terminal of the over voltage protection switch is higher than a voltage rating of an input terminal of the reverse blocking switch, and/or higher than a voltage rating of an input terminal of the conversion switch, wherein the control circuit further generates an over voltage control signal to control a control terminal of the over voltage protection switch.

7. The charger circuit of claim 6 , wherein the control circuit includes a first regulation comparator and/or a second regulation comparator, wherein the first regulation comparator is configured to operably compare a charging current related signal and a regulation current threshold to generate a regulation current comparison result, and control the over voltage protection switch according to the regulation current comparison result, such that the charging current is regulated to be not larger than a predetermined regulation current level; and the second regulation comparator is configured to operably compare a charging voltage related signal and a regulation voltage threshold to generate a regulation voltage comparison result, and control the over voltage protection switch according to the regulation voltage comparison result, such that the charging voltage is regulated to be not larger than a predetermined regulation voltage level.

8. The charger circuit of claim 6 , wherein the charger circuit includes plural over voltage protection switches, wherein the plural over voltage protection switches are configured to operably sense and control currents flowing through the over voltage protection switches such that each current flowing through each of the over voltage protection switches is substantially the same.

9. The charger circuit of claim 1 , further including a cable and/or a connector, coupled between the power delivery unit and the capacitive power conversion circuit, or coupled between the power delivery unit and the reverse blocking switch circuit, wherein the cable and the connector are compliant to the Universal Serial Bus or Universal Serial Bus Power Delivery (USB or USB PD) specifications, and the cable and/or the connector includes a power line and a signal line, wherein the power line is coupled to the DC power and the signal line is configured to operably transmit one or more of a DC current related signal, a DC voltage related signal, a charging current related signal, and a charging voltage related signal.

10. A capacitive power conversion circuit for use in a charger circuit which is configured to operably convert an input power to a DC power and convert the DC power to a charging power for charging a battery, wherein the DC power includes a DC voltage and a DC current and the charging power includes a charging voltage and a charging current, the capacitive power conversion circuit comprising: a conversion switch circuit, configured to operably convert the DC power to a converted output power which includes a converted output voltage and a converted output current, wherein the charging power is related to the converted output power; wherein the conversion switch circuit includes plural conversion switches, configured to be coupled to at least one conversion capacitor, wherein at least one of the conversion switches includes a body diode; a control circuit, configured to operably generate a conversion switch control signal to control the plural conversion switches; and at least one reverse blocking switch circuit, coupled with the battery and the conversion switch circuit in series, and configured to block a parasitic body current flowing through the body diode of the conversion switch, wherein the reverse blocking switch circuit includes at least one reverse blocking switch which has a body diode, and the body diode of the reverse blocking switch is reversely coupled to said body diode of the conversion switch; wherein in a charging mode, during plural charging conversion time periods in a cycle period, the conversion switch control signal operates the plural conversion switches so as to electrically connect the conversion capacitor between a pair of nodes selected from one or more charging voltage division nodes, the DC voltage, and a ground node periodically, such that the charging current is scaled-up of the DC current substantially by a predetermined factor, the factor being larger than 1 whereby the charging current is larger than the DC output current, and/or the charging voltage is substantially a predetermined voltage ratio of the DC voltage; wherein the converted output power is generated through one of the one or more charging voltage division nodes.

11. The capacitive power conversion circuit of claim 10 , wherein the charger circuit further includes at least an over voltage protection switch, wherein a voltage rating of an input terminal of the over voltage protection switch is higher than a voltage rating of an input terminal of the reverse blocking switch, and/or higher than a voltage rating of an input terminal of the conversion switch, wherein the control circuit further generates an over voltage control signal to control a control terminal of the over voltage protection switch.

12. The capacitive power conversion circuit of claim 11 , wherein the control circuit includes a first regulation comparator and/or a second regulation comparator, wherein the first regulation comparator is configured to operably compare a charging current related signal and a regulation current threshold to generate a regulation current comparison result, and control the over voltage protection switch according to the regulation current comparison result, such that the charging current is regulated to be not larger than a predetermined regulation current level; and the second regulation comparator is configured to operably compare a charging voltage related signal and a regulation voltage threshold to generate a regulation voltage comparison result, and control the over voltage protection switch according to the regulation voltage comparison result, such that the charging voltage is regulated to be not larger than a predetermined regulation voltage level.

13. The capacitive power conversion circuit of claim 11 , wherein the control circuit controls currents flowing through the over voltage protection switches to be substantially the same as one another.

14. A reverse blocking switch circuit for use in a charger circuit which is configured to operably convert an input power to a DC power and convert the DC power to a charging power for charging a battery, wherein the DC power includes a DC voltage and a DC current and the charging power includes a charging voltage and a charging current, wherein the charger circuit comprises: a power delivery unit which is configured to operably convert the input power to the DC power; and a capacitive power conversion circuit, including: a conversion switch circuit, configured to operably convert the DC power to a converted output power which includes a converted output voltage and a converted output current, wherein the charging power is related to the converted output power; wherein the conversion switch circuit includes plural conversion switches, configured to be coupled to at least one conversion capacitor, wherein at least one of the conversion switches includes a body diode; the reverse blocking switch circuit being coupled with the battery and the conversion switch circuit in series, and configured to block a parasitic body current flowing through the body diode of the conversion switch; the reverse blocking switch circuit comprising: at least one reverse blocking switch which has a body diode, and the body diode of the reverse blocking switch is reversely coupled to said body diode of the conversion switch; a regulation protection switch, coupled in series with the reverse blocking switch; and a first regulation comparator and/or a second regulation comparator, wherein the first regulation comparator is configured to operably compare a charging current related signal and a regulation current threshold to generate a regulation current comparison result, and control the regulation protection switch according to the regulation current comparison result, such that the charging current is regulated to be not larger than a predetermined regulation current level; and the second regulation comparator is configured to operably compare a charging voltage related signal and a regulation voltage threshold to generate a regulation voltage comparison result, and control the regulation protection switch according to the regulation voltage comparison result, such that the charging voltage is regulated to be not larger than a predetermined regulation voltage level; wherein in a charging mode, during plural charging conversion time periods in a cycle period, the conversion switch control signal operates the plural conversion switches so as to electrically connect the conversion capacitor between a pair of nodes selected from one or more charging voltage division nodes, the DC voltage, and a ground node periodically, such that the charging current is scaled-up of the DC current substantially by a predetermined factor, the factor being larger than 1 whereby the charging current is larger than the DC output current, and/or the charging voltage is substantially a predetermined voltage ratio of the DC voltage; wherein the converted output power is generated through one of the one or more charging voltage division nodes.